BR102013015965B1 - Noise Blocking for High Frequency Receivers and Method for Blocking Noise in a High Frequency Receiver - Google Patents

Abstract

NOISE BLOCKING FOR HIGH RECEIVERS, NOISE BLOCKING METHOD. A noise block for the radio frequency receiver is described including a first signal detector which is configured to detect the presence of a useful signal in a received signal (29). The first signal detector includes a delay device (24) which is designed to delay a signal (32) derived from the received signal (29) by a delay period. The first signal detector further comprises a minimum detector (25) which is configured to form the minimum signal (34) as the minimum of the signal obtained from the received signal (32) and the delayed signal obtained from the received signal ( 33).

Description

[0001] The invention relates to a noise blocking for high frequency receivers and a method for blocking noise in high frequency receivers.

[0002] To detect the presence of a useful signal in a received signal, the signal-to-noise ratio of the received signal is conventionally studied in mobile equipment and aeronautical devices. When the signal to noise ratio exceeds a threshold value of the useful band, this will be detected as the presence of a useful signal.

[0003] Thus, the German patent DE 199 37 199 A1 shows a noise blocking for high frequency digital receivers which detects the presence of a useful signal on the basis of the signal-to-noise ratio.

[0004] However, particularly in the presence of several useful signals in the received signal, an unfavorable signal-to-noise ratio often occurs at the boundary between two transmission areas of different channels, although up to two useful signals are contained in the received signal.

[0005] To face this difficulty, the signal level of the carrier signal is also analyzed within the useful band. As soon as the signal level exceeds a certain value, regardless of the current signal-to-noise ratio, noise blocking is deactivated and thus the signal becomes audible.

[0006] However, the level-based noise blocking described above is sensitive to pulse interference. Therefore, in the high frequency performance standards (MOPS Minimum Operating Performance Standards) of the civil aviation flight control service (ATC Air Traffic Control) immunity to short and recurrent pulse interference has been defined. The defined interference pulses have a duration of 10μs at a repetition rate of 1 kHz. Due to the high high frequency level of the pulse, the average value of the resulting level is higher than the threshold of sensitivity of the level-based noise block, despite the relationship between the short pulse duration and the pause duration being 1%. These requirements, however, cannot be satisfied with conventional noise blocking and level detection.

[0007] The invention is based on the task of creating a noise block and a method for using noise blocking that reliably detects the presence and absence of useful signals.

[0008] According to the invention, the task is solved for noise blocking by the features of independent claim 1 and for the method by the features of independent claim 8. Advantageous developments are targets of the corresponding dependent claims.

[0009] According to the invention, for high frequency receivers, noise blocking includes a first signal detector configured to detect the presence of a useful signal in a received signal. The first signal detector also includes a delay unit, which is configured to delay a signal derived from the received signal by the delay time. The first signal detector further includes a minimum detector which is designed to form a minimum signal in the form of a minimum of the signal derived from the received signal and the delayed signal derived from the received signal. Thus, reliable removal of interference from the received signal is possible. In this way, noise blocking reliability is significantly increased.

[0010] The first signal detector preferably further includes an averaging unit which is configured to determine the minimum signal duration and thereby average the signal. The first signal detector preferably further includes a comparator which is configured to compare the average of the signal to the first threshold value. Exceeding the first threshold value indicates the presence of a useful signal in the received signal. Thus, a certain signal strength is shown in the comparison. From there, conclusions can be drawn about the strength of the signal within the band and, therefore, also about the useful signal. Thus, noise blocking becomes reliably conductive also in the case of two carrier signals (eg the CLIMAX aeronautical radio) or distorted signals (eg in emergency transmitters).

[0011] The delay time is between 10μs and 500μs and preferably between 20μs and 200μs and particularly preferred between 50μs and 100us. An adaptation to the interference pulses to be compensated or to a modulation scheme of the received signal is possible. Here, the signal is delayed to the extent absolutely necessary, as too long a delay can result in unstable noise blocking with vibrations. The delay time is preferably chosen as a function of the transmitted signal. Thus, depending on the modulation or the type of interference signal, different delay times may result.

[0012] Preferably, the noise blocking includes at least one filtering unit which is configured to filter a signal obtained from the received signal before the signal is transmitted to the delay device. Thus, limiting the signal band is achieved.

[0013] Preferably, the noise blocking further includes a second signal detector, which is configured to detect upon transgression of a second threshold value in the signal-to-noise ratio of the received signal, the presence of a useful signal in the received signal. Thus, greater noise blocking reliability can be achieved using only one signal detector.

[0014] Noise blocking still has the advantage of having a discriminator, which is designed to decide that there is a useful signal in the received signal, if at least one signal detector detects a useful signal in the received signal. This fact also increases the noise blocking reliability. Preferably, the discriminator is designed as an OR operation. Thus, noise blocking becomes a conductor in the event of a response from one of the detectors.

[0015] The noise blocking further includes a Mute switch, which is designed to connect a signal obtained from the received signal with a signal output, when at least one signal detector indicates the presence of a useful signal in the received signal. Thus, reliable opening of noise blocking can be achieved when received signals are difficult.

[0016] In the method for blocking noise in high frequency receivers, according to the invention, the presence of a useful signal in a received signal is detected in a receiving channel. A signal obtained from the received signal is delayed by the delay time. A minimum signal is formed as the minimum of the signal derived from the received signal and the delayed signal derived from the received signal. Thus, recurrent pulses of high energy interference (frequency packets, also on the receive channel) can be effectively suppressed.

[0017] Next, the invention is described as an example by means of a drawing in which an advantageous example of carrying out the invention is shown. The drawing shows:

[0018] Fig. 1 is a first embodiment of the present invention as a block diagram of noise blocking;

[0019] Fig. 2 a second example of embodiment of the noise block, according to the invention with a detailed view of the block diagram;

[0020] Fig. 3a an exemplary signal received with interference pulses.

[0021] Fig. 3bum first received signal from a baseband received signal, with widened interference pulses;

[0022] Fig. 3cum second signal derived from a signal received via time shift;

[0023] Fig. 3 of the first and second signals obtained from the signal received from a superimposed presentation;

[0024] Fig. 3 and a third signal formed from the first and second derived signals, in which noise pulses are strongly suppressed, and

[0025] Fig. 4 is a first example of embodiment of the method according to the invention in flowchart form.

[0026] Firstly, with reference to Figures 1 - 2, the illustrated construction and the type of operation of two examples of embodiment of the noise blocking are explained, according to the invention. Figures 3a to 3e are detailing the exact function. Finally, with reference to Figure 4, the function of the exemplary embodiment of the method is illustrated, according to the invention. Parts of identical elements have not been shown again and described in similar Figures.

[0027] Figure 1 shows a first example of implementation of the noise block, according to the invention. Connected to an input terminal 10 is the processing device 11, which in turn is connected to the Mute switch 12.

[0028] Connected to the mute switch end 12 is speaker 13. Connected to the signal input terminal 10 are a first signal detector 15 and a second signal detector 16. Signal detectors 15 and 16 they can in turn be connected to a discriminator 17, which is connected to the Mute switch 12. The processing means comprises an audio processing block. This is used to filter a frequency range from 30 to 2500 Hz and a boost. The signal detector 15 operates based on the signal-to-noise ratio. Signal detector 16 operates based on the useful band level. The discriminator works as an OR operation.

[0029] At input terminal 10, a received signal is fed. Possible preprocessing is not shown here. The first signal detector 15 and the second signal detector 16 preferably detect, through different methods, the presence of a useful signal in the received signal and pass the result of this detection to the discriminator 17. The discriminator 17 decides based on the results from the detection of signal detectors 15 and 16, whether a desired signal is present in the received signal or not. The discriminator preferably performs an OR operation. That is, as soon as one of the signal detectors 15 or 16 detects the presence of a useful signal in the received signal, the discriminator 17 decides that a useful signal is present in the received signal. Based on the result of this decision, discriminator 17 controls Mute switch 12.

[0030] The received signal is additionally transmitted to the processing means 11, which continue with the process, transforming it into an analog audio signal. The processing means 11 passes the resulting signal to the input terminal of the mute switch 12. If the discriminator 17 decides that a useful signal is contained in the received signal, it controls the mute switch 12 such that the output signal of the means 11 is transmitted to speaker 13. However, if it has been decided by discriminator 17 that there is no useful signal in the received signal, it controls Mute switch 12 in such a way that the output signal from processing means 11 is discarded.

[0031] Figure 2 shows a second example of implementation of noise blocking, according to the invention. Here only one signal detector is shown which, for example, corresponds to the signal detector 16 of Figure 1. The filter unit 20 is connected to the input terminal 10, which is connected to the analog-digital converter 21. , in turn, is connected to the digital frequency converter 22. This is connected to the delay unit 24. The delay unit 24 is connected to the minimum detector 25, which is connected to the averaging unit 26. This, by turn is connected to comparator 27. In addition, the output terminal of the frequency converter is connected to minimum detector 25.

[0032] At input terminal 10, a receive signal 29 is provided. The received signal 29 is filtered by the filtering unit 20 and transmitted as filtered received signal 30 to the analog-digital converter 21. The filtering consists of an intermediate frequency filtering. Analog-digital converter 21 digitizes signal 20 to received signal 31, digitizes the filtrate. This is transmitted to the digital frequency converter 22, which transforms it into baseband and transmits it as a baseband signal 32 to filtering means 23. In this case, a channel selection is carried out by a FIR filter within the frequency converter 22. Due to the filtering in the FIR filter inside the frequency converter 22 and as a function of the filtering in the filtering unit 20, a temporal expansion of interference pulses is effected, since the signal bandwidth is reduced.

[0033] The digital baseband signal 32 is transmitted to the delay unit 24 which delays the signal by the delay time Δt. Simultaneously, the delayed digital baseband signal 33 is supplied to the minimum detector 25. The minimum detector 25 chronologically determines the minimum of each signal 32 and 33 generating, based on these facts, the minimum signal 34. The minimum signal 34 is then transmitted to unity to calculate the average 26, which forms the chronological average of the signal. The signal energy is thus distributed over time.

[0034] The resulting average signal 35 is transmitted to comparator 26 which compares it to the threshold value. If the averaging signal 35 exceeds the threshold value, that fact is detected as the presence of a useful signal in the received signal. However, if the averaging signal 35 is less than the threshold value, this fact is detected in the received signal as the absence of a useful signal. The comparator 26 outputs the binary decision signal 36 as an output signal.

[0035] In Figure 3a, input signal 29 of Figure 2 is also shown. Here, the signal includes a series of high-amplitude interference pulses of short chronological length. Here, each pulse has, for example, a duration of 10μs and an interval of 1 ms. The amplitude of the pulses corresponds, in the example, to 3 mV. Figure 3a also shows the threshold value 11, which is used for detecting a useful signal in the received signal. Without signal processing according to the invention, each interfering pulse is interpreted as a useful signal as it exceeds the threshold value.

[0036] In Figure 3b, the digital baseband signal 32 of Figure 3 is shown. Filtering by the FIR filter inside the frequency converters 22 and filtering through the filtering unit 20 has caused the energy of each interference pulse to be distributed over time, as the bandwidth of the input signal 29 has been limited. The wrists thus became a little wider. In the representation chosen here, the pulses are shown with exaggerated width. In reality, the pulses become wider due to a small factor of, say, 10 or more, wider than in the original input signal 29.

[0037] In Figure 3c, the delayed digital baseband signal 33 is now shown. The signal corresponds exactly to signal 32, but is time shifted.

[0038] In Figure 3d, the digital baseband signal 32 and the time-shifted digital baseband signal 33 are now shown. Clearly visible here is the delay time Δt. It corresponds to 60 μs from here. Of course, signals 32 and 33 do not overlap at their ends, but overlap at their base.

[0039] In Figure 3e, the sign of the resulting average 35 is shown. This signal corresponds to the overlapping parts of signals 33 and 34 of Figure 3d which are averaged over time. In addition, the threshold value 11 is displayed again. It is clearly seen that the minimum signal 11 exceeds the threshold at no point. In this way, any interference pulses of Figure 3a are no longer detected as a useful signal.

[0040] However, a true useful signal cannot be filtered in this way, as it does not consist only of short duration interference pulses. In principle, the useful signal is not changed by the method shown here, because it does not pass through the delay unit 24 nor through the minimum detector 25.

[0041] Figure 4 shows an example of carrying out the method according to the invention. In a first step 40, a received signal is filtered. This filtration is a pre-processing. The parts of the signal outside the useful band, for example, are removed. In a second step 41, digitization of the filtered signal takes place. Then, in the third step 42, the digital signal is subjected to a frequency shift. Here, the signal is transformed into baseband. By limiting the signal band in the first step 40 filtering and frequency shifting, individual interference pulses are distributed over time.

[0042] In a fourth step 43, a delay of the resulting signal is performed by the delay time Δt. The delay time Δt is an order of magnitude of the width of the interference pulses to be removed.

[0043] In a fifth step 44, the minimum of the delayed signal and the non-delayed signal is formed. By this means, the high peaks are removed from the signal. In a sixth step 45, the average is calculated. That is, the signal energy is distributed over time.

[0044] Finally, the resulting signal is compared with the threshold value in the seventh step 46. If the signal becomes lower than the threshold value, this fact is detected as the absence of a useful signal in the received signal. If the minimum signal exceeds the threshold value, this is detected as the presence of a useful signal in the received signal.

[0045] The additional steps of signal processing of the received signal and the triggering, respectively blocking of the output signal, in the presence respectively in the absence of a useful signal, are not shown here.

[0046] The invention is not limited to the illustrated embodiment example. As mentioned above, a plurality of different signal detectors can be used. All the features described above or shown in the figures can be combined with each other in a desired and advantageous way within the scope of the present invention.

Claims (13)

1. Noise blocking for high frequency receivers with a first signal detector (16) which is configured to detect the presence of a useful signal in a received signal (29), wherein the first signal detector (16) comprises a delay unit (24) which is configured to delay a signal (32) obtained from the received signal (29) by a delay time, characterized in that the first signal detector (16) comprises a minimum detector (25) ) which is configured to form a minimum signal (34) as the minimum of the signal (32) obtained from the received signal and the delayed signal (33) obtained from the received signal, where the delay time is situated between 20μs and 200 µs and wherein the first signal detector (16) further comprises an averaging unit (26) which is configured to average the minimum signal over time and thereby generate an averaging signal (35 ), wherein the first signal detector (16) further comprises a comparator (27) which is configured to compare the average signal (35) with a first threshold value, wherein a transgression of the first threshold value indicates the presence of a useful signal in the received signal (29). 2. Noise blocking, according to claim 1, characterized in that the delay time is between 50μs and 100μs, and in which the delay time is adjusted depending on a width of interference pulses to be suppressed or depending on a type of modulation of the received signal (29). 3. Noise blocking according to any one of claims 1 or 2, characterized in that the noise blocking comprises at least one filtering unit (26) which is configured to filter the minimum signal (34). 4. Noise blocking, according to any one of claims 1 to 3, characterized in that the noise blocking further comprises a second signal detector (15) which is configured to detect the presence of a useful signal in the received signal by transgressing a second threshold value by a signal-to-noise ratio of the received signal (29). 5. Noise blocking, according to claim 4, characterized in that the noise blocking further comprises a discriminator (17) that is configured to decide that a useful signal is present in the received signal (29) when at least one signal detector (15, 16) detects a useful signal in the received signal (29). 6. Noise blocking, according to any one of claims 1 to 5, characterized in that the noise blocking further comprises a Mute switch (12), which is configured to switch a signal obtained from the received signal (29). ) to a signal output when at least one signal detector (15, 16) indicates the presence of a useful signal in the received signal (29). 7. Method for blocking noise in a high frequency receiver, wherein the presence of a useful signal in a received signal (29) is detected, wherein a signal (32) derived from the received signal (29) is delayed by the delay time, characterized in that a minimum signal (34) is formed as the minimum of the signal (32) derived from the received signal and the delayed signal (33) derived from the received signal, wherein the delay time is situated between 20μs and 200μs and where the minimum signal (34) is averaged over time and thus an average signal (35) is generated, and where the average signal (35) is compared to a first value threshold, wherein a transgression of the first threshold value indicates the presence of a useful signal in the received signal (29). 8. Method according to claim 7, characterized in that the delay time is between 50μs and 100μs, and in which the delay time is adjusted depending on a width of interference pulses to be suppressed or depending on a type of modulation of the received signal (29). 9. Method according to any one of claims 7 or 8, characterized in that the minimum signal (34) is filtered. 10. Method according to claim 9, characterized in that the average is performed in the time domain. 11. Method according to any one of claims 7 to 10, characterized in that the presence of a useful signal in the received signal (29) is detected through a transgression of a second threshold value by a signal-to-noise ratio of the received signal (29). 12. Method according to claim 11, characterized in that it is decided that a useful signal is present in the received signal (29) when a useful signal is detected in the received signal (29) by means of at least one of the methods as defined in any one of claims 7 to 11. 13. Method according to any one of claims 7 to 12, characterized in that a signal derived from the received signal (29) is switched to a signal output when the presence of a useful signal in the received signal (29) is determined by at least one of the methods as defined in any one of claims 7 to 12.

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